Building Construction Using A Structural Insulating Core

ABSTRACT

The present invention relates to an improved wall system where a wall uses spacer blocks between framing members to form a structural insulating core. The spacer blocks interlock horizontally and vertically using a means of forming a tongue and groove connection between the spacer blocks and between the framing members. Various interlocking tongue and groove connections form different wall structures and horizontal bracing channels along with the horizontal tongue and trough add flexibility. Metal channels and wood are used as framing members and the structural insulation core assembly can form structural insulated panels (SIP&#39;s). A coupling is used to connect vertical framing members and brackets are shown connecting spacer blocks than full height framing members.

REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of patent application Ser. No. 12/456,707 filed Jun. 22, 2009 and Ser. No. 12/231,875 filed on Sep. 8, 2008.

BACKGROUND OF THE INVENTION

(1) Field of the Invention

The present invention relates to an unproved wall system where the structural insulating core uses various wall forming structures and various shapes of spacer blocks interconnecting between each other forming horizontal and vertical tongue and groove connections between spacer blocks. The improved wall system. is also used to form a roof system.

BACKGROUND OF THE INVENTION

Exterior metal framing has always been difficult to insulate because of the configuration of the support channels like a C channel. The lip and flange of the C channel protrudes from the web making it difficult to insulate. When horizontal bracing channels are installed between support channels for additional strength, insulation became even more difficult to install as well as form a good insulated wall.

Closed cell rigid insulation has been increasing in popularity, however the solutions has been to mold the closed cell insulation into the support channels. In addition, closed cell rigid insulation has been cut into panels where several support channels slide into the rigid insulation panel from the top of the rigid insulation in order to install the support channels. The closed cell rigid insulation solutions are usually installed in a manufacturing plant rather that at the job site.

The creation of a smaller spacer blocks that has flexibility to be assembled into panels at a manufacturing plant or at the construction site as well as incorporating various types of horizontal bracing channels and electrical chases or troughs gives the spacer block additional flexibility. In addition, the size of the spacer block can vary depending on the type of closed cell rigid insulation is used like polystyrene, cellular light weight concrete or aerated autoclaved concrete.

The horizontal bracing channels within the wall forming structure is generally provided by installing bridging members which tie the support channels together. These bridging members may be attached on the outside of the flanges of the support channels or maybe internal bridging members installed through openings provided in the web of the support channels. None of the bridging members used today have a limited function and do not provide a solution for interacting with rigid insulation between support channels and the holes the internal bridging members pass through.

The construction of a wall varies based on the type of materials that are used. For example a solid concrete or masonry wall does not need to be laterally supported, because the wall is connected horizontally from say one masonry block to another masonry block. On the other hand, a post and beam type construction needs to be horizontally braced somewhere within that building otherwise the building would collapse if the wind or an earthquake would cause the building to move horizontally. Usually that is done by adding diagonal braces that criss-cross between the columns or by adding a solid wall somewhere within the building structure. When a smaller wood or metal framed wall has a similar problem, that is, the framing members need to be supported between each other using by applying plywood over the framing members. The plywood acts a shear wall, by not allowing the framing members to fall down like “domino's”.

Structural insulated panels or SIP's have a foam core with exterior skins usually plywood glued to the foam. Sometimes metal or wood is installed within the foam core and the wood or metal is connected between the panels for additional support. SIP's have a very limited load bearing capacity due to the structural limitation in the design of the panels. The use of SIP's have been limited to one or two story building and have never been used in conjunction with precast or poured-in-place concrete walls.

(2) Description of Prior Art

A. Foam Block with Holes

In U.S. Pat. No. 5,842,276 by Ashner cuts a hole in a larger block so a conduit can be installed. The block remains as one piece and a tongue and groove connection is not incorporated in the assembly of the synthetic panel.

In U.S. Pat. No. 7,028,440 (filed Nov. 29, 2003) by Brisson uses foam blocks with vertical holes to form concrete columns and uses a horizontal recess at the top of the panels to form a beam pocket. The foam panels are made using a tongue and groove type connections between panels and the panels are glued together. Since the holes for the concrete are only support by foam, the size is limited as the concrete will deform as well as break the foam panels. Again the beam pocket is also fragile as there is not support to stop the wet concrete from deforming the beam.

B. Foam Panel

In U.S. Pat. No. 5,943,775 (filed Jan. 7, 1998) and U.S. Pat. No. 6,167,624 (filed Nov. 3, 1999) by Lanahan uses a polymeric foam panel with metal channels installed within the foam. The panels are interlocked together by a tongue and groove connection using the foam as the connector. An electrical conduit is horizontally installed within the panel for electrical distribution. The metal channels are embedded within the foam. None of the Lanahan patents use their panels to form concrete columns or beams. Walpole in U.S. Pat. No. 7,395,999 embeds a metal channel in foam for support and uses a tongue & groove joint sealer between panels. In U.S. Pat. No. 5,722,198 (filed Oct. 7, 1994) and U.S. Pat. No. 6,044,603 (filed Feb. 27, 1998) by Bader discloses a panel & method to form a metal channel and foam panel where the flanges are embedded into the sides of the foam panels. In U.S. Pat. No. 5,279,088 (filed Jan. 17, 1992), U.S. Pat. No. 5,353,560 (filed Jun. 12, 1992) and U.S. Pat. No. 5,505,031 (filed May 4, 1994) by Heydon show a wall and panel structures using overlapping foam and metal channels in various configurations.

C. SIP

Structural insulated panels known as SIP's are typically made using rigid insulation in the middle with plywood on both sides and wood blocking or metal connectors are installed in the middle connecting the two panels together.

Porter has developed many SIP patents using metal components including U.S. Pat. No. 5,497,589, U.S. Pat. No. 5,628,158, U.S. Pat. No. 5,842,314, U.S. Pat. No. 6,269,608, U.S. Pat. No. 6,308,491, and U.S. Pat. No. 6,408,594 as well as Babcock U.S. Pat. No. 6,256,960, Brown U.S. Pat. No. 6,564,521 and Kligler U.S. Pat. No. 6,584,742 of which Babcock shows a metal channel between two panels to interlock adjacent panels. In U.S. Pat. No. 5,638,651 uses metal channels at interior but does not have a thermal break on the metal channels. Porter shows 5 more patents using wood and one more U.S. Pat. No. 5,950,389 using splines to interlock panels.

D. Panel Construction

In U.S. Pat. No. 5,638,651 filed Jun. 21, 1996 by Ford uses an interlocking panel system where two U channels interlocks with an OSB board and the metal channel to form a building panel. In U.S. Pat. No. 6,701,684 filed Jun. 26, 2002 by Stadler uses vertical back to back U metal channels in a foam panel and a cementous coating over the foam to form a wall. In U.S. Pat. No. 6,880,304 filed Sep. 9, 2003 by Budge uses a vertical slotted frame to support a foamed wall assembly.

SUMMARY OF THE INVENTION

The present invention relates to an improved wall system where a structural insulating core wall uses various wall forming structures and spacer blocks interconnecting between each other. The spacer blocks have vertical and horizontal interlocking tongue and groove connections that connect between the wall forming structure and the spacer blocks. The spacer blocks can cover the flanges of the support channels or just protrude beyond the support channels to form a thermal break.

Another variation of the invention is when the spacer blocks are wider than the support channels, and overlap the flanges of the support channels in various different ways. The inner and outer boards that are installed over the spacer blocks are not in contact with the support channels and create a thermal break in the improved wall system.

Brackets which are shorter than full height support channels can be used when constructing a wall forming structure. The brackets also have a hole into which the horizontal bracing channel can connect to allowing the spacer blocks to be secured together when load bearing materials can be used rather than closed cell insulation materials.

Another aspect of the invention is that exterior wall sheathing and interior rigid insulation in a wall are formed as one and together form an integrated material referred to a spacer block. The integrated wall sheathing speeds construction since usually two different construction trades installs the wall sheathing and the interior insulation and the spacer blocks provides a measurement say 16″ or 24″ on center for a faster wall installation.

Another aspect of the pending patents it the formation of a structural insulating panel (SIP) when the structural insulating core and the rigid board and rigid insulating are all glued together

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an isometric view of the structural insulating wall where the spacer blocks are wider and interlock between the support channels and horizontal bracing channels and horizontal tongue fit into a trough of the spacer blocks connecting to the support channels together along with the base plate connections to the spacer blocks and support channels.

FIG. 2 show a plan view with the tongue and groove assembly using the reverse lip channel as the support channel of the structural insulating core.

FIG. 3 shows a plan view of the overlapping projections of the thinner tongue space and groove space of the spacer block with a C channel wall structure.

FIG. 4 shows an isometric view of a half wall and the tongue and groove connection between the spacer blocks.

FIG. 5 is a plan view showing the half wall with the tongue and groove connection and the horizontal bracing channel supporting the spacer blocks.

FIG. 6 shows a plan view of the spacer block with the projection and extension on the tongue side of the spacer block.

FIG. 7 shows an isometric view of FIG. 2 using the reverse lip channel as the support channel.

FIG. 8 shows an isometric view of a hat channel as the support channel which is similar to FIG. 7.

FIG. 9 shows an isometric view of the U channel as the support channel and the projection and extension of the spacer block overlapping the flange.

FIG. 10 shows an isometric view of the U channel as the support channel where the projection and extension of the spacer block and the tongue side of the spacer block are on the same side.

FIG. 11 shows an isometric of the bracket and horizontal bracing channel connected.

FIG. 12 shows an isometric with the bracket and spacer block together.

FIG. 13 shows an isometric of two channels connected by a coupling.

FIG. 14 shows a perspective view of 3 spacer blocks where the spacer blocks have the projection and extension on the same side as tongue side.

FIG. 15 shows a wall section of FIG. 13.

FIG. 16 shows a perspective view of 3 spacer blocks being secured when the spacer blocks overlap the flange at the tongue side of the spacer blocks.

FIG. 17 shows a wall section of FIG. 15.

FIG. 18 show a roof section of the spacer blocks where the spacer blocks extend to the flange of the roof support channel.

FIG. 19 shows the roof section of the spacer blocks having an extension added to the projection of the spacer blocks.

FIG. 20 shows the spacer blocks at the roof sliding together.

FIG. 21 shows an isometric of one profile of the spacer block with a smaller spacer block below.

FIG. 22 shows a wall plan view of the projection and extension of the spacer block extending over one side of the wood framing member.

FIG. 23 shows a wall plan view of the projection and extensions of the spacer block extending over both sides of the wood framing member.

FIG. 24 shows a wall section at the wood framing member

FIG. 25 shows the wall section at the spacer blocks interlocking between each other.

FIG. 26 shows an isometric view of a full height wall where the spacer blocks are the width of the support channels.

FIG. 27 shows a plan view of the full height wall

DESCRIPTION OF THE PREFERRED EMBODIMENTS

FIG. 1 shows an isometric drawing and FIG. 3 shows a plan view of the structural insulating core 111 where vertical support channels are the supporting wall structure of the structural insulating core 111 and the spacer blocks 56 fit between the C channels 42. The left side shows the wall assembled and the right side shows the various wall components separated. The right side shows the support channel as a C channel 42 with the horizontal bracing channel 150 shown as a horizontal U channel 155 passing through the hole 36 in the web 42 a of the C channel 42. On both sides of the C channel 42 are spacer blocks 56 that have a trough 132 at the top of each spacer block 56. The horizontal U channel 155 fits through the hole 36 and into the troughs 132 of the spacer blocks 56. Another spacer block 56 is shown above the horizontal U channel 155 where a horizontal tongue 56 t fits into the trough 132 of the spacer block 56 below. The trough 132 is deeper than the horizontal U channel 155 so to allow space for any mechanical/electric utilities to pass through. All the spacer blocks 56 are shown deeper than the length of the web 42 a of the support channel so projection 56 p can extend over the flanges 42 b of the C channel 42. The spacer blocks 56 have a tongue shape 56 a that fits between the lips 42 c and abut the webs 42 a and the lip 42 c of the C channels 42 and a groove shape 56 b where the groove shape abuts the web 42 a of the C channel 42 and the projections 56 p of the spacer block 56 extends over the flanges 42 b of the C channel 42 abutting the adjacent spacer block 56. The base plate 120 is shown also as a horizontal U channel 155, however the web 155 a is secured to a floor and the webs 155 b are attached to the flanges 42 b of the C channel 42 and the flanges 421, also slide into a groove 121 at the bottom of the spacer block 56. The left side of FIG. 1 shows the wall panel 65 consisting of the structural insulating core 111 assembled together with the rigid board 50 and rigid insulation 51 are the inner and outer rigid boards that define the outer surfaces of the wall panel 65. Also shown are drainage channels 151 that protrude from the structural insulating core 111 to create an air space should it be required when some exterior surface finish materials (not shown) are applied over the structural insulating core 111. In addition a recessed groove 133 is shown on the exterior face of the structural insulating core 111 to allow water drainage between the structural insulating core 111 and various stucco applications. The recessed grooves 133 and drainage channels 151 can become accents at the exterior face of the structural insulating core 111.

FIG. 2 shows a plan view of FIG. 1 except here two reverse lip channels 79 are used between three spacer blocks 56. The reverse lip channel 79 is similar to the C channel 42 in FIG. 1, except the lip 79 c is bent in the opposite direction as the lip 42 c. The tongue shape 56 a fits against the web 79 a of the reverse lip channels 79 and the groove shape 56 b fits against the adjacent reverse lip channel 79 at the web 79 a and the projection 55 p of the spacer block 56 fits against the flanges 79 b and abuts the lip 79 c. Since the structural insulating core 111 has a snug fit between the reverse lip channels 79 and the spacer blocks 56, the wall panel 65 can be glued together. The reverse lip channel 79 and the C channel 42 have the same physical characteristics since the lip 79 c & 42 c function in the same way giving the reverse lip channel 79 the same strength as the C channel 42. In addition, the reverse lip channel 79 can also be use in place of the horizontal bracing channel 150 where ever it has been used.

FIG. 4 is similar to FIG. 1 except the four spacer blocks 56 of the structural insulating core 111 is less than the thickness of the spacer blocks 56 in FIG. 1. The groove shape 56 b of the spacer block 56 has a projection 56 p and extension 56 e that extends beyond the webs 42 a of the adjoining C channels 42 enough to create a thermal break and cover the C channels 42. The open portion of the C channel 42 has a web 42 a and a lip 42 c where the tongue shape 56 a fits against and between and a horizontal bracing channel 150 (typically used to connect adjacent C channels within the building industry) and an indentation 56 i where the extension 56 e fits against. Since the spacer blocks 56 overlaps the C channel 42 at the projection 56 p and fits between the webs 42 a, the spacer block 56, the spacer block 56 becomes a wall insulation as well as a wall sheathing material all made together as one material. The vertical connection between the spacer blocks 56 has a horizontal tongue 56 t the width of the projection 56 p and extends downward into the indentation 56 i of the spacer block 56 below. FIG. 5 is a plan view of the wall panel 65 showing the tongue shape 56 a and groove shape 56 b and the projection 56 p and extension 56 e of the spacer block 56 between the C channels 42 as shown also in FIG. 4.

FIG. 6 shows a plan view of a structural insulating core 111 with an alternated shape for the spacer block 56. The spacer block 56 shows the tongue shape 56 a with the projection 56 p and extension 56 e on the same side of the spacer block 56. The tongue shape 56 a is similar to FIG. 1 where the tongue shape 56 a fits between the lips 42 c of the C channels 42 and abuts the web 42 a when installed in place. In FIG. 6 the projection 56 p with the extension 56 e extends past the web 42 a and is longer than the flange 42 b of the C channel 42. The additional length, of the projection 56 p is shown as an extension 56 e of the spacer block 56 is the equal to the length of the flange 42 b plus the length of the indentation 56 i where the spacer block 56 abuts is longer than the flange 42 b of the C channel 42 thereby overlapping the adjacent spacer block 56. What is shown in FIG. 6 is that the spacer block 56 can be cut into any configuration and still be installed next to an adjacent C channel 42 using the same configured spacer block 56. The support member in the structural insulating core can be formed with wood framing 68 or the C channel 42 as shown in FIGS. 21-24, however the tongue space 56 a is not required in the spacer block 56 and the horizontal bracing channel 150 is not required. Inner and outer boards as shown in FIG. 1 can be installed over the structural insulating core to form a structural insulated panel (SIP). In addition, a cementitious coating 195 (not shown) can be installed on any of the spacer blocks 56 prior to being installed in the C channels 42.

FIG. 7 shows an isometric view of the plan view shown in FIG. 2. The projections 56 p are extended from the groove side 56 b of the spacer block 56. The projections 56 p abut the lips 79 c of the reverse lip channel 79. The reverse lip channel 79 is shaped similar to the C channels 42 which are commonly used in the building industry. The reverse lip channel has a web 79 a with flanges 79 b bent at 90 degrees to the web 79 a and two lips 79 c that are bent 90 degrees from the flanges 79 b, but are bent away from the web 79 a. The web 79 a has holes 36 that are aligned between reverse lip channels 79 so horizontal bracing channels 150 can pass through. FIG. 7 as shows the trough 132 at the top of the spacer block 56 so the horizontal bracing channel 150 can secure the spacer blocks 56 to the support channels.

FIG. 8 shows an isometric view of a hat channel 70 used as a support channel between spacer blocks 56. Since the hat channel 70 has angular flanges shown as 70 b there is no means to make a secured connection to a base plate 121 as shown in FIG. 1 to the flange 70 b of the hat channel 70. The hat channel 70 with the horizontal bracing channel 150 makes a vertical and horizontal connection between spacer blocks 56 as shown and explained in FIG. 12.

FIG. 9 is an isometric view of the structural insulation core 111 where U channels 41 are the support channels rather than the C channels 42 shown in FIG. 1. The spacer blocks 56 are shown with the groove side 56 b abuts the web 41 a and the projections 56 p fits against the flanges 41 b and the extension 56 e rests against the indentation 56 i of the tongue side 56 a of the adjacent spacer block 56. The horizontal bracing channel 150 shown as a horizontal U channel passes through the holes 36 of the U channel 41 and into the trough 132 of the spacer blocks 56. The horizontal tongue 56 t on the spacer blocks 56 fit into the trough 132 interlocking the projections 56 p with their extensions 56 e, the U channel, and the trough 132 and tongue 56 t together.

FIG. 10 shows an isometric view of a structural insulating core 111 with an alternated shape for the spacer block 56 as shown in FIG. 6 except a U channel 41 is used as the support channel. The spacer block 56 shows the tongue shape 56 a with the projection 56 p and extension 56 e on the same side of the spacer block 56. The projection 56 p with the extension 56 e extends past the web 41 a and is longer than the flange 41 b of the U channel 41. The additional length of the projection 56 p is shown as an extension 56 e of the spacer block 56 is the equal to the length of the flange 41 b plus the length of the indentation 56 i on the groove side 56 b where the spacer block 56 abuts is longer than the flange 41 b of the U channel 41 thereby overlapping the adjacent spacer block 56.

FIG. 11 is an isometric of a bracket that consists of a short support channel and a short horizontal bracing channel passing through the hole in the web of the support channel. The bracket is shown as a U channel 41 with a hole 36 in the web 41 a where the horizontal U channel 155 is secured at the hole 36. The bracket 138 can be of one piece where the horizontal bracing channel 155 is a solid connection at the hole 36 or two separate pieces. FIG. 12 shows the bracket 138 and horizontal U channel 155 connects adjacent spacer blocks 56 as shown in FIGS. 13-16. When the bracket 138 is used as two separate components, the support channel shown as U channel 41 is short that is only extending to the top two and bottom two spacer blocks 36 and the horizontal bracing channel 150 connects to many brackets 138 within the length, of the building wall. When this occurs, the support channels as shown in FIGS. 11-12 & 14-17 are not structural supports for the structural insulating core 111. The spacer blocks 36 are made of a load beating blocks and the brackets 138 are used as a mortarless joint construction or dry stacking the spacer blocks 56 together. FIG. 14 shows an isometric view and FIG. 15 a wall section of the bracket 138 with the spacer blocks 56 shown with the projections 56 p and extensions 56 e located on the tongue side 56 a of the spacer blocks 56. FIG. 16 shows an isometric view and FIG. 17 a wall section of the bracket 138 with the spacer blocks 56 shown with the projections 56 p and extension 56 e located on the groove side 56 b of the spacer blocks 56.

FIG. 13 shows and isometric view of reverse lip channel 79 with a coupling 63 between the U channels 41 connecting both of the channels together. The coupling 63 can be used to connect any support channels together that have flanges perpendicular to the web. The coupling 63 is shown connecting to the webs 79 a & 41 a, as well as the flanges 79 b & 41 b to the flanges 63 b and web 63 a of the coupling 63. The coupling 63 can be connected to the inner surface or outer surface of the reverse lip channel 79 and U channel 41.

FIG. 18-20 shows various roof sections which are similar to the wall sections of the structural insulating core 111 described earlier. The support channels for a roof are typically deeper as shown in the C channel 42 as well as the depth of the spacer blocks 56 than a building wall. The profile of the spacer block 56 in FIG. 18 is similar to the profile at the plan view shown in FIG. 4 except the C channels 42 are shown deeper and the spacer block 56 is thicker. In FIG. 18 the wall panel 65 the spacer blocks 56 can have a rigid 50 added to the bottom of the wall panel 65 or can be one piece where the rigid board 50 is part of the spacer block. One side of the spacer blocks 56 fits against the webs 42 a and against the lips 42 c of the C channel 42. If the support channel was a U channel 41 (not shown) then the spacer block would rest directly on the flange 41 b. The other side of the spacer blocks 56 rests against the web 42 a of the adjacent C channel 42 and the projection 56 p rests on the upper flange 42 b. In FIG. 19 the projection 56 p and extension 56 e is longer, similar to FIG. 4, and the extension 56 e rests on the indentation 56 i of the adjacent spacer block 56. The projection 56 p and extension 56 e overlapping onto the indentation 56 i forms a greater thermal break in the spacer block 56 as compared to FIG. 17. FIG. 20 is the same profiles as the spacer blocks in FIG. 19, however spacer block 56 has an increased thickness (shown in ghost) with another projection 56 p and extension 56 e added on the same side as the lip 42 c and flange 42 b of the C channel 42. Again the adjacent spacer block 56 has the indentation to accept the extension 56 e of the spacer block 56 shown at an angle. The groove side 56 b shows a projection 56 p with the extension 56 e is shown overlapping the flange 42 b on top of the C channel 42 and the tongue side 56 a of the spacer block 56 shows the projection 56 p with the extension 56 e extending under the flange 42 b of the adjacent C channel 42. The lower extension 56 e adds support to the spacer block 56. By having the projection 56 p below the support channel, the connection between C channels is less obstructive than having both projections 56 p on the same tongue side 56 a or the same groove side 56 b. The roof section in FIG. 20 can also be used as a plan view of any of the previous described wall constructions.

FIG. 21 shows two spacer blocks 56 without the C channel 42 as shown in FIG. 15. The spacer block 56 consists of a width W, the spacing distance between support channels; a height H shown as h1 and h2, the height of the spacer blocks which will vary depending on the height of the wall; and thickness T, the thickness of a wall or thickness of the spacer block 56. The thickness T of the spacer block 56 is greater than the depth of the support channel to allow for projections 56 p to extend over the flanges 42 b on both sides of a support channel. The vertical connection between spacer blocks 56 is a tongue and groove connection described earlier as a tongue side 56 a that fits into and between the U shape created by the web 42 a and flanges 42 b and abuts the lips 42 c of the C channel 42 as shown in FIG. 15. The opposite side of the spacer block 56 is shown with the groove side 56 b which abuts the web 42 a of the C channel 42 and has projections 56 p that extend over both flanges 42 b. FIG. 20 shows extensions 56 e that allow the projection 56 p with its extension 56 e to overlap onto an adjacent spacer block 56. The overlap is shown on the tongue side 56 a where an indentation 56 i is shown to accept the extension 56 e from an adjacent spacer block 56. FIG. 1 shows the same spacer block as described here, but without the extension 42 e added to the projection 42 p. The horizontal connection between spacer blocks 56 is also a tongue and groove connection described earlier as a trough 132 which is a groove that is shown as a rectilinear shape, but can be any shape so the horizontal tongue 56 t can from an adjacent spacer block 56 can fit into the trough 132. The trough 132 is deeper than the tongue 132 to allow any horizontal mechanical passage between support channels and spacer blocks 56. The lower spacer block 56 shows a vertical hole 36 v passing through the trough 132 and/or the horizontal tongue 56 t (not shown) if need be. The spacer blocks 56 can be stacked vertically together and grooves 121 (shown as a single dashed line) can be installed on the top or bottom of the spacer blocks 56 to form a wall. The spacer blocks 56 can be made from a variety of closed cell materials that resist heat transfer like polystyrene, aerated autoclave concrete, concrete with polystyrene beads and cellular lightweight concrete. The spacer blocks 56 can be installed with or without fasteners as well as with or with mortar. The spacer block 56 profile would typically be cut by a hot wire machine for polystyrene; however the spacer block 56 profile can also be molded.

FIGS. 22-25 shows the spacer block 36 installed between a wood framing system consisting of wood framing members 68 spaced apart from one another and wood plates 67 connecting the wood framing members 68 together which is standard wood framing construction techniques. Between the wood framing members 68, spacer blocks 56 are shown with a tongue side 56 a and a groove side 56 b and is wider than the depth of the wood framing members 68. The tongue side 56 a abuts the wood framing member 68 and extends past the wood framing member 68 so an indentation 56 i and a projection 56 p with an extension 56 e can be installed as shown in FIG. 23. The tongue side 56 a has indentations 561 on both sides of the spacer block 56. The groove side 56 b also abuts the wood framing member 68 and has projections 56 p extend to the opposite side of the wood framing member 68 and an extension 56 e is added to the end of the projection 56 p so the projection 56 p and extension 56 e become one element as shown in numerous earlier figures forming a vertical connection between spacer blocks. The horizontal connection between spacer blocks 56 also has a tongue and groove connection as shown in FIG. 24. The spacer block 56 in FIG. 25 shows a projection 56 p extending over both sides of the wood plate 67 at the floor 175. The upper portion of the spacer block 56 show a horizontal tongue 56 t extending above the spacer block 56 the width of the wood framing members 68 which creates an indentation 56 i at the top of the spacer block 56. The bottom of the spacer block 56 and the spacer block 56 above shows a horizontal projection 56 p that fits into the indentation 56 i of the spacer block 56 and the horizontal tongue 56 t is fitting into the trough 132 in the above spacer block 56. A horizontal brace 78 can be continuous or installed as shorter segments to connect wood framing members 68 together. The horizontal brace 78 is shown installed between the horizontal projections 56 p and the indentation 561 and can also be installed into the grooves 121 at the projections 56 p and indentations 56 i. Above the projection 56 p shown dotted is another trough 132 that is used to distribute mechanical systems (electric or plumbing lines) if a hole 36 (dashed) is installed in the framing member. Another horizontal connection is shown when a wood plate 67 is installed in the middle of the wall (required by some building code officials). When the horizontal connection between the framing members is required, an extension 56 e is used to maintain the tongue and groove connection. FIG. 22 is similar to FIG. 23 in that only one projection 56 p is used and the thickness of the spacer blocks 56 is narrower.

FIG. 26 shows an isometric view of the structural insulating core 111 where the depth of the spacer blocks are the same as the width of the structure channels shown as C channels 42. The inner and outer boards shown on rigid board 50 and rigid insulation 51 can be part of the structural insulating core 111 or be added after the wall is erected into a vertical position. The left side of the spacer block 56 is referred to as the tongue side 56 a where the spacer block 56 is installed between the lip 42 c the depth of the flange 42 b and abuts the web 42 a of the C channel 42 and the opposite side or groove side of the spacer block 56 b abuts the web 42 a of an adjacent C channel 42. Since not all spacer blocks 56 may want to extend the full height of the structural insulating core 111, the spacer block 56 abut between each other by connecting together the horizontal tongue 56 t of one spacer block 56 fits into a trough 132 of another spacer block 56. The trough 132 can be the depth of the horizontal tongue 56 t or can be extended deeper to allow of mechanical/utilities to pass through the trough 132 which is larger in size. The horizontal tongue 56 t and the trough 132 align when the hole 36 of the web 42 a and the horizontal bracing channel 150 shown as the horizontal U channel 155 passes into the trough 132 and allows the horizontal bracing channel 150 to connect the C channels 42 together. On the other hand, if the trough 132 is just deep enough for the horizontal bracing channel 150, the width of the horizontal tongue 56 t is narrower so the horizontal tongue 56 t fits into the horizontal U channel 155. The plan view FIG. 28 also shows the intersection of the spacer block 56 sliding horizontally between the lips 42 c connecting the tongue side 56 a into the C channel 42. The full height wall includes the base plate angles 99 connecting to the concrete floor 39′ and the support channels as well as the base plate 120 at the top of the structural insulating core 111. The drainage channels 151 are shown on the spacer blocks 56 so moisture could escape when a finish material (not shown) is installed over the spacer blocks 56.

CONCLUSION AND SCOPE OF INVENTION

The structural insulating core consists of structural support members and spacer blocks that fit between the structural support members. The spacer blocks are thermal blocks that are wider than the support members that interlock between other spacer blocks and structural support members which when assembled together form a wall. Several types of support members such as metal channels or wood framing members fit between the support members and interlock together with a tongue and groove connections both vertically and horizontally. Many different configurations of the vertical and horizontal tongue and groove connections are shown. Horizontal bracing channels interlock between the support members and spacer blocks along with the horizontal tongue and trough connects interlock the spacer blocks together. The tongue and groove connections allow the spacer blocks to just slide together without fasteners or mortar to hold them in place.

The spacer blocks with the tongue and groove connections can have short support channels and horizontal bracing channels to hold the spacer blocks together. Full height support channels can be used with short horizontal bracing channels to construct a wall as well as short support channels and long horizontal bracing channels connecting many spacer blocks together can also for a wall.

The structural insulating core can be used as an independent wall, screwed or glued to together to form a SIP or together to form a larger structural insulated panels.

It is understood that the invention is not to be limited to the exact details of operation or structures shown and describing in the specification and drawings, since obvious modifications and equivalents will be readily apparent to those skilled in the art. The flexibility of the described invention is very versatile and can be used in many different types of building applications. 

1. A structural insulating core wall of a building consisting of: spaced apart vertically oriented metal support channels with holes, horizontal bracing channels, spacer blocks positioned between and at least spanning the distance between the channels, the blocks consisting of: a block depth dimension being substantially greater than the distance between channel flanges, a groove and a transverse mating tongue fully extending along a transverse length of facing, opposed side block surfaces, the groove and tongue surfaces contacting and encompassing the two channel flanges, a trough and horizontal tongue fitting together and aligned with holes in support channels, a base angle groove running perpendicular to the tongue and groove, the base angle groove in a bottom block face and positioned from a front or a back block surface a dimension equal to a foam thickness from the front or the back of the block to the channel flange; and, a base plate having flanges inserted in a base angle grooves of the blocks; the base plate flanges secured to the channel flanges, and secured to a building floor adjacent the structural insulating core wall.
 2. The structural insulating wall of claim 1 including a block depth dimension being greater than a distance between channel flanges, the groove and tongue surfaces contacting and encompassing the channel flanges.
 3. The structural insulating core wall of claim 1 wherein the structural insulating core can be installed at an angle to form a roof.
 4. The structural insulating core wall of claim 1 wherein the support channel is a reverse lip channel that consists of a web with two flanges that are each bent 90 degrees to the web and bent again 90 degrees forming a lip that extends outward from the two flanges in an opposite direction to the lip of a C channel.
 5. A structural insulating core wall of claim 1 wherein the trough is large enough to accommodate mechanical means in the trough and through the holes in the support channels.
 6. A structural insulating core wall of claim 1 wherein the spacer block is between vertically oriented metal support channels positioned between, and at least spanning the distance between the channels and between horizontally spaced apart members connected to the vertically oriented metal support channels and positioned between and at least spanning the distance between the horizontally spaced members comprising of: a horizontal block dimension positioned between and at least spanning the distance between the vertically oriented metal support channels; wider than the width of the web of the support channels and overlaps the flanges of the vertical channels support; and interlocking between causing a tongue shape and a groove shape between the vertical support channels a vertical block dimension positioned between and at least spanning the distance between the horizontally spaced apart members; a width equal to the width of the horizontal block dimension; a horizontal trough wherein a horizontally spaced apart member fits into and aligns with the holes of the vertical support channels; a horizontal tongue that fits into the horizontal trough of an adjacent spacer block.
 7. A structural insulating core wall of claim 6 wherein the support channel has; a web, a perpendicular or slope flange, either no lip or a lip that is turn toward the web or away from the web into which the tongue side of the spacer block fits into.
 8. A structural insulating core wall of claim 6 wherein the tongue side of the spacer block has; a projection on one flange or both flanges, a projection and extension over one or both flanges, an indentations the length of the extension extending to the outer surfaces of the spacer block.
 9. The structural insulating core wall of claim 3 wherein the spacer block has a tongue side fitting against the web and flanges of the support channels with a block face having an indentation and the opposed block face has a projection and extension over the support channel; the groove side fits against the web on the support channel with a block face having an indentation and the opposed block face having a projection and extension of the support channel; and where block face has an indentation and a projection and extension.
 10. The structural insulating core wall of claim 6 wherein the groove side of the spacer block abuts; the web of the support channels, the web and lip of the support channels, no projections and extends to the outer surfaces or an indentation the length of the extension extending to the outer surfaces of the spacer block.
 11. A spacer block wall of a building is formed as blocks consisting of: evenly spaced, spacer blocks positioned between each other, and above each other, interlocking and consisting of: a block depth dimension corresponding to the wall depth, a block width having groove and a transverse mating tongue full extending along the transverse length of facing, opposed side block surfaces, an interlocking tongue space and groove space so the tongue shape has a recesses into which the projections can overlap the adjoining spacer block to fit into, a block height having a horizontal recess forming a trough, opposed side block surfaces, a horizontal tongue so as into fit into the trough of an adjacent spacer block.
 12. A spacer block according to claim 6 where grout can be installed between adjacent blocks.
 13. The spacer block according to claim 11 wherein a vertical hole is install full, height of the spacer block.
 14. The spacer block according to claim 11 wherein the spacer blocks have a projection plus an extension and the opposed side has an indentation for the extension to rest upon.
 15. The spacer blocks according to claim 11 wherein the spacer blocks have protruding drainage channels and recessed grooves on the surface of the space block for architectural accents and reliefs to control water drainage.
 16. A connector for structural insulating core wall is formed wherein a vertical support channel and a horizontal bracing connect adjoining spacer block together comprising of a short vertical support channel and a short horizontal bracing channel intersect and are secured together by the horizontal bracing channel by passing through the hole in the web of the vertical support channel forming a brace connector, the brace connector with the two ends of the short vertical support channel and the two ends of the short horizontal bracing channel connect the four adjacent spacer blocks together whereby: the short vertical support channel fits into the groove space at the side of the spacer block and the horizontal bracing channel fits into the trough at the top of the spacer block, a second spacer block is installed adjacent to the vertical support channel and the projections of the second spacer block overlaps the vertical support channel and the horizontal bracing channel fits into the trough at the top of both the first and second spacer blocks, a third spacer block is installed above the horizontal bracing channel of the first spacer block and the tongue at the bottom of the third spacer block fits into the trough on top of the first spacer block and the tongue space of the third spacer block fit between the flanges of the vertical support channel, a fourth spacer block is installed above the second spacer block and the tongue at the bottom of the fourth spacer block fits over the horizontal bracing channel in the trough on top of the second spacer block and the projections of the fourth spacer block is installed over the flanges of the vertical support channel, the vertical support channel and the horizontal bracing channel are short and need only be connect to the spacer blocks adjacent to the brace connector.
 17. The brace connector according to claim 16 wherein the short horizontal bracing channel fits tight into the hole in the web of the short vertical support channel locking the two channels together to form a one piece brace connector.
 18. The brace connector according to claim 16 can be a T shape wherein only three spacer blocks intersect the brace connector.
 19. The brace connector according to claim 16 wherein the brace connector is only the short vertical support channel overlapping two adjacent spacer blocks by overlapping the adjacent spacer blocks.
 20. The brace connector according to claim 16 wherein the brace connector is only the short horizontal bracing channel that fits into the troughs of two adjacent spacer blocks interlocking the spacer blocks together.
 21. A coupling support channel in the structural insulation core of claim 1 wherein support channels are connected end to end by a coupling consisting of a web and two flanges and where the flanges and the web fits between the web and flanges of two adjacent support channels so the flanges and the web of the two adjacent support channels align with each other forming a continuous support channel.
 22. A structural insulating core wall of a building consisting of spaced apart vertically oriented wood framing members, horizontal base plates, spacer blocks positioned between and at least spanning the distance between the framing members, the blocks consisting of: a block depth dimension being substantially greater than the depth of the framing members, a projection with an extension and a transverse mating tongue fully extending along a transverse length of facing, opposed side block surfaces, the groove and tongue surfaces contacting and encompassing the framing members, a trough and horizontal tongue fitting together and aligned between spacer blocks, a base plate groove running perpendicular to the tongue and groove, the base plate groove in a bottom block face and positioned from a front or a back block surface a dimension equal to a foam thickness from the front or the back of the block to the base plate; and, a base plate having inserted into the trough of the blocks, the base plate secured to the framing members, and secured to a building floor through the structural insulating core wall.
 23. The structural insulating core wall of claim 22 wherein a horizontal framing member connects between the vertically oriented wood framing members and the trough fit over the horizontal framing member and the projections extend over the width of the horizontal framing member.
 24. The structural insulating core wall of claim 23 wherein the projections of the spacer block has an extension that extends into an indentation of the adjacent spacer block for the extension to fit into.
 25. The structural insulating core wall of claim 22 wherein the vertically oriented wood framing members has a hole in the middle to align with a trough above the groove in the spacer block.
 23. A spacer block wall according to claim 11 wherein the spacer block can be formed within molds conforming to the desired shape of the block.
 24. A spacer block wall according to claim 11 wherein the spacer block can be formed within a mold for a portion of the block configuration and cut to obtained an additional configuration.
 25. The structural insulating foam core wall of claim 1 wherein the support channels from the structural insulated core can extend into the footing.
 26. A structural insulating foam core wall of a building consisting of: evenly spaced vertically oriented metal support channels, foam spacer blocks positioned between and at least spanning the distance between the channels, the blocks consisting of: a block depth dimension being greater than the distance between the inside edge of the horizontal bracing channel and extending past the outer channel flanges, a groove and a transverse mating tongue fully extending along a transverse length of facing, opposed side block surfaces, the groove and tongue surfaces contacting and encompassing one of the two channel flanges, a horizontal projection extends over the adjacent spacer block surface onto an indentation of the block spacer below, a base plate groove running perpendicular to the tongue and groove, the base plate groove in a bottom block face and positioned from a front or a back block surface a dimension equal to a foam thickness from the front or the back of the block to the channel flange; and, a base plate having a base plate flange inserted in a base plate groove of the blocks, the base plate secured to the channel flanges, and, the base plate web parallel to a building floor and secured to a building floor within the structural insulating foam core wall.
 27. The structural insulating core wall of claim 22 wherein a horizontal brace connects wood framing members together between horizontal projections of one spacer block and the indentations of the adjacent spacer block.
 28. The structural insulating core wall of claim 27 wherein the spacer blocks have a groove at the horizontal projections and indentations of adjacent spacer blocks for the horizontal brace to fit into.
 29. A structural insulating core wall of a building consisting of: spaced apart vertically oriented metal support channels with boles, horizontal bracing channels, spacer blocks positioned between and at least spanning the distance between the channels, the blocks consisting of: a block depth dimension being the same distance between channel flanges, a groove and a transverse mating tongue fully extending along a transverse length of facing, opposed side block surfaces, the groove and tongue surfaces contacting and encompassing the two channel flanges, a trough and horizontal tongue fitting together and aligned with boles in support channels, a base angle groove running perpendicular to the tongue and groove, the base angle groove in a bottom block face and positioned from a front or a back block surface a dimension equal to a foam thickness from the front or the back of the block to the channel flange; and, a base plate having flanges inserted in a base angle grooves of the blocks; the base plate flanges secured to the channel flanges, and secured to a building floor adjacent the structural insulating core wall. 